DE10357176A1 - capacitor - Google Patents

Abstract

The condenser has a collecting pipe separated by a separation wall (7). An accumulator has inner and outer shells, which are coaxially arranged to each other so that a flow channel (16) for a cooling unit is formed between the shells. An inflow-or discharge opening communicates with a space enclosed by the inner shell. Another inflow-or discharge opening is arranged in the outer shell. A dryer and a filter (29) is provided in the space. The latter opening is provided at a front side end of the pipe. The accumulator is provided laterally adjacent to a pipe-ribs-block.

Description

The Invention relates to a condenser for the air conditioning system of a motor vehicle, whose tubes can be traversed by the refrigerant in several stages, for which he has two headers, and one, with one of the headers over one and outflow openings between the stages in fluid communication standing, collector has, approximately parallel to the tubes of the Condenser is arranged.

Such a condenser with vertically extending heat exchanger tubes is from the 7 of EP 769 666 A1 known. In EP 666 the headers are arranged horizontally lying. The collector runs parallel to the heat exchanger tubes of the condenser and is arranged vertically upright. The vertical position of the collector is favorable with respect to the separation therein between still gaseous and already liquefied refrigerant, and is therefore the most widespread.

in the EP 974 793 A2 . 1 on the other hand, the heat exchanger tubes are horizontal and thus the collecting tubes of the local condenser are arranged vertically standing. The collector is located horizontally parallel to the heat exchanger tubes, below the tube-fin block of the condenser. Incidentally, it has been provided in this document that the refrigerant flows through the collector following the passage of the stages of the condenser, which is why this condenser belongs to a different type.

In both cases the collector is solvable, about one soldered Connecting block, connected to one of the manifolds. It seems no inventive step to be required for the detachable connection into an insoluble, for example, in a solder joint, remodel.

however has the inventor about it addition, the task made his capacitor even more compact and even more production-friendly than overall soldering construction train.

According to the invention this object has been achieved in a capacitor according to the preamble of claim 1 with the features of its characteristics. There is provided a transfer line from one stage to the one inlet or outlet opening of the collector. The transfer line extends approximately over the area of the adjacent stage. The other inlet or outlet opening of the collector is provided approximately at the front end of the manifold. As a result, a particularly compact arrangement was created, which can be perfectly combined to form a single Lötkonstruktion. Each stage consists of several parallel heat exchanger tubes of the condenser. Furthermore, the provision of the transfer line improves the position of the collector. In the 7 of EP 769 666 A1 the collector is located in front of or behind the pipe-fin block, so that the heat exchange between the cooling air flowing in perpendicular to the pipe-fin block and the refrigerant flowing inside the pipe-fin block is impaired. By contrast, according to the invention, the collector is laterally adjacent to the tube and fin block, thereby improving the efficiency of heat exchange. With the help of the transfer line, the refrigerant is transferred from one stage to the other via the other stage into the collector. After flowing through the collector, the refrigerant enters the mentioned other stage and flows through it. This other stage may, for example, be a subcooling stage.

The transfer line can be located either inside the header or outside the header be. The compactness is further enhanced when one within the collecting pipe arranged transfer line chosen becomes. This may be an approximately coaxial tube. The Collecting tube could in the area of the transmission line but also be divided only by a wall. The other Inlet or outlet opening preferably directly between the jacket of the collector and the provided at the end face of the manifold. Thereby the collector in the immediate vicinity of the tube-rib block and in particular in the immediate vicinity and parallel to one of the side panels that usually connects the tube-and-rib block reinforce the pages. If necessary, an additional Holder of the collector are provided.

Of the inventive capacitor is particularly suitable for combination with a water cooler and / or other heat exchangers of the motor vehicle, which is also top and bottom horizontally arranged collection boxes and vertical heat exchanger tubes exhibit.

following the invention in two preferred embodiments with reference to the enclosed pictures. Go from this description Further features and advantages of the invention, which can be as especially significant.

The 1 - 4 show an execution Example, with an external transfer line and the 5 - 9 show an embodiment with an integrated transfer line in the manifold. The 9 shows a flared manifold with integrated transfer line.

The steps indicated in the exemplary embodiments 1 and 2 each consist of several flat heat exchanger tubes 15 , being between the heat exchanger tubes 15 corrugated fins 18 are arranged, which are flowed through by the cooling air to the refrigerant in the heat exchanger tubes 15 to cool or condense. The refrigerant leaves the condenser in the fully liquefied and supercooled state 30 ,

In the in the 1 and 5 shown sections of the capacitor 30 is it therefore at the stage 1 around several stages, which are upstream, as it is in principle from the 2 and 6 is recognizable. The steps 1 . 2 arise due to the convenient arrangement of partitions 7 in the headers 3 and 5 ,

In the 1 and 2 the refrigerant enters 25 through the inlet and outlet flange 26 in the condenser 30 one. It flows through several stages 1 before passing through the inlet opening 27 into the transfer line 10 entry. Through the transfer line 10 becomes the entire refrigerant 25 at the stage 2 passed by and into the collector 4 transferred. At the flange 8th enters the transfer line 10 in the collector 4 and cross the room 28 , the filter 29 and gives above the filter 29 the liquid mixed with low gas fractions refrigerant 25 over the inflow opening 14 into the interior of the collector 4 from. In the collector 4 the desiccant is in a container 12 , On its way the refrigerant flows through the filter 29 to separate the smallest particles and into the backflow space 28 , The dividers 36 should guarantee that the entire refrigerant 25 through the filter 29 flows. About the discharge opening 13 on the flange 9 leaves the refrigerant 25 the collector 4 and flows through the front end 35 of the manifold 3 in the stage 2 of the capacitor 30 , After hypothermia in the stage 2 it passes through the manifold 5 and the outlet 19 to the inlet and outlet flange 26 to then continue on his way in the air conditioning cycle, not shown. In 4 an alternative to the first embodiment is shown. In some cases it may be necessary to the collector 4 something in front of or behind the plane 33 the tube-fin block of the capacitor 30 to arrange. The collector 4 is then the distance 32 out of the plane 33 offset to the front or back, but otherwise identical to the first embodiment.

In 5 and 6 the refrigerant enters 25 through the inlet and outlet flange 26 in the condenser 30 one. It flows through several stages 1 before passing through the inlet opening 27 into the transfer line 10 entry. Through the transfer line 10 becomes the entire refrigerant 25 at the stage 2 passed by and into the collector 4 transferred. At the flange 8th enters the transfer line 10 in the collector 4 one. At the bottle 8th is also the inlet opening 14 through which the refrigerant 25 in an inner jacket 20 flows. In the inner coat 20 the desiccant is in a container 12 , On its further way it passes the filter arranged above the dryer 29 to separate the smallest particles. Between the outer jacket 31 of the collector 4 and the inner jacket 20 is the flow channel 16 through which the refrigerant 25 can flow down. Over the discharge opening 13 on the flange 9 leaves the refrigerant 25 the collector 4 and flows through the front end 35 of the manifold 3 in the stage 2 of the capacitor 30 , After hypothermia in the stage 2 it passes through the manifold 5 and the outlet 19 to the inlet and outlet flange 26 , In 8th is still an alternative to the second embodiment shown. In some cases it may be necessary to the collector 4 something in front of or behind the plane 33 the tube-fin block of the capacitor 1 to arrange. The collector 4 is then the distance 32 out of the plane 33 offset to the front or rear, but otherwise identical to the second embodiment.

In 9 Yet another alternative of the second embodiment is shown. Here is just a section of the manifold 3 to see. In this case, the manifold was 3 on the collector 4 facing side 35 enlarged in diameter. Before the last partition 7 in the manifold 3 is the collector pipe 3 widened to the transfer line 10 absorb, so that the recirculating refrigerant 25 no unnecessary pressure loss due to a too narrow manifold 3 experiences. In addition, the installation of the transfer line 10 easier to accomplish.

Claims (13)

Capacitor ( 30 ) for the air conditioning system of a motor vehicle whose parallel heat exchanger tubes ( 15 ) in several stages ( 1 . 2 ) of a refrigerant ( 25 ) are flowed through, for which he has two headers ( 3 . 5 ), which by means of partitions ( 7 ) are divided such that the mentioned and from several heat exchanger tubes ( 15 ) existing levels ( 1 . 2 ), and the one with one of the manifolds ( 3 ) via inlet and outlet openings ( 13 . 14 ) between the steps ( 1 . 2 ) in flow connected collector ( 4 ), which is approximately parallel to the heat exchanger tubes ( 15 ) of the capacitor is arranged, characterized that a transfer line ( 10 ) of a stage ( 1 ) to the one inlet or outlet ( 14 ) of the collector ( 4 ) is provided, which in the transverse direction of the tubes ( 15 ) about an adjacent stage ( 2 ) and that the other inlet or outlet opening ( 13 ) of the collector ( 4 ) at the front end ( 35 ) of the manifold ( 3 ) or in the vicinity thereof, to transfer the refrigerant to the adjacent stage ( 2 ). Capacitor according to Claim 1, characterized in that the transfer line ( 10 ) within the manifold ( 3 ) is arranged. Capacitor according to Claim 1, characterized in that the transfer line ( 10 ) outside the manifold ( 3 ) is arranged and preferably parallel thereto. Capacitor according to Claims 1 and 2, characterized in that the transfer line ( 10 ) at one end in an opening in the partition wall ( 7 ) and the inlet opening ( 27 ) and at the other end into the collector ( 4 ) entry. Capacitor according to Claims 1 and 3, characterized in that the transfer line ( 10 ) at one end near the dividing wall ( 7 ) in the manifold ( 3 ) and the inlet opening ( 27 ) and at the other end in the collector ( 4 ) plugged. Capacitor according to one of the preceding claims, characterized in that the collector ( 4 ) an inner jacket ( 20 ) and an outer jacket ( 31 ), which are preferably arranged coaxially to each other, so that between the inner shell ( 20 ) and the outer jacket ( 31 ) a flow channel ( 16 ) for the refrigerant ( 25 ), wherein the one inlet or outlet opening ( 14 ) with the inner shell ( 20 ) and the other inlet or outlet ( 13 ) in the outer jacket ( 31 ) is arranged. Capacitor according to one of the preceding claims, characterized in that in the space defined by the inner shell ( 20 ) is enclosed a dryer ( 12 ) and a filter ( 29 ) are located. Capacitor according to one of the preceding claims, characterized in that in the space defined by the inner shell ( 20 ) is enclosed a dryer ( 12 ) and a filter ( 29 ) in the flow path in front of the outflow opening ( 14 ) is arranged. Capacitor according to one of the preceding claims, characterized in that the filter ( 29 ) above the dryer ( 12 ) is arranged so that the purified refrigerant ( 25 ) after flowing through the filter ( 29 ) reverses its flow direction and via the flow channel ( 16 ) and the other inlet or outlet opening ( 14 ) into the said stage ( 2 ) of the capacitor occurs. Condenser according to one of the preceding claims, characterized in that the collecting pipes ( 3 . 5 ) of the capacitor ( 30 ) extend horizontally, so that the heat exchanger tubes ( 15 ) of the capacitor ( 30 ) and the parallel collector ( 4 ) are arranged vertically. Condenser according to one of the preceding claims, characterized in that both inlet or outlet openings ( 13 . 14 ) laterally in the interior ( 20 ) or outer jacket ( 31 ) of the collector ( 4 ) are arranged. Condenser according to one of the preceding claims, characterized in that the one flange ( 8th ) in the bottom of the collector and the other flange in its vicinity in the outer shell ( 31 ) of the collector ( 4 ) is arranged. Condenser according to claim 2, characterized in that the collecting pipe ( 3 ) over the length of the transfer line ( 10 ) has a larger diameter than in the remaining length range, to the installation of the transfer line ( 10 ) to facilitate.